Your search keyword '"Yiwang Ye"' showing total 3 results

1. Whole-genome synthesis and characterization of viable S13-like bacteriophages.

Author

Yuchen Liu, Yonghua Han, Weiren Huang, Yonggang Duan, Lisha Mou, Zhimao Jiang, Pingping Fa, Jun Xie, Ruiying Diao, Yuanbin Chen, Yiwang Ye, Ruilin Yang, Jing Chen, Xiaojuan Sun, Zesong Li, Aifa Tang, Yaoting Gui, and Zhiming Cai

Subjects

Medicine, Science

Abstract

BackgroundUnprecedented progresses in high-throughput DNA sequencing and de novo gene synthesis technologies have allowed us to create living organisms in the absence of natural template.Methodology/principal findingsThe sequence of wild-type S13 phage genome was downloaded from GenBank. Two synonymous mutations were introduced into wt-S13 genome to generate m1-S13 genome. Another mutant, m2-S13 genome, was obtained by engineering two nonsynonymous mutations in the capsid protein coding region of wt-S13 genome. A chimeric phage genome was designed by replacing the F capsid protein open reading frame (ORF) from phage S13 with the F capsid protein ORF from phage G4. The whole genomes of all four phages were assembled from a series of chemically synthesized short overlapping oligonucleotides. The linear synthesized genomes were circularized and electroporated into E.coli C, the standard laboratory host of S13 phage. All four phages were recovered and plaques were visualized. The results of sequencing showed the accuracy of these synthetic genomes. The synthetic phages were capable of lysing their bacterial host and tolerating general environmental conditions. While no phenotypic differences among the variant strains were observed when grown in LB medium with CaCl(2), the S13/G4 chimera was found to be much more sensitive to the absence of calcium and to have a lower adsorption rate under calcium free condition.Conclusions/significanceThe bacteriophage S13 and its variants can be chemically synthesized. The major capsid gene of phage G4 is functional in the phage S13 life cycle. These results support an evolutional hypothesis which has been proposed that a homologous recombination event involving gene F of quite divergent ancestral lineages should be included in the history of the microvirid family.

Published

2012

2. Chemical synthesis of bacteriophage G4.

Author

Ruilin Yang, Yonghua Han, Yiwang Ye, Yuchen Liu, Zhimao Jiang, Yaoting Gui, and Zhiming Cai

Subjects

Medicine, Science

Abstract

BACKGROUND: Due to recent leaps forward in DNA synthesis and sequencing technology, DNA manipulation has been extended to the level of whole-genome synthesis. Bacteriophages occupy a special niche in the micro-organic ecosystem and have potential as a tool for therapeutic agent. The purpose of this study was to carry out chemical synthesis of the bacteriophage G4 and the study of its infectivity. METHODOLOGY/PRINCIPAL FINDINGS: Full-sized genomes of bacteriophage G4 molecules were completed from short overlapping synthetic oligonucleotides by direct assembly polymerase chain reaction and ligase chain reaction followed by fusion polymerase chain reaction with flanking primers. Three novel restriction endonuclease sites were introduced to distinguish the synthetic G4 from the wild type. G4 particles were recovered after electroporation into Escherichia coli and were efficient enough to infect another strain. The phage was validated by electron microscope. Specific polymerase chain reaction assay and restriction analyses of the plaques verified the accuracy of the chemical synthetic genomes. CONCLUSIONS: Our results showed that the bacteriophage G4 obtained is synthetic rather than a wild type. Our study demonstrated that a phage can be synthesized and manipulated genetically according to the sequences, and can be efficient enough to infect the Escherichia coli, showing the potential use of synthetic biology in medical application.

Published

2011

3. Whole-genome synthesis and characterization of viable S13-like bacteriophages

Author

Aifa Tang, Yaoting Gui, Lisha Mou, Zhiming Cai, Yuanbin Chen, Zhimao Jiang, Ruilin Yang, Yiwang Ye, Jing Chen, Ruiying Diao, Pingping Fa, Yuchen Liu, Yonggang Duan, Zesong Li, Jun Xie, Yonghua Han, Weiren Huang, and Xiaojuan Sun

Subjects

Phage display, Phagemid, viruses, Genome, Bacteriophage, Genome Databases, Bacteriophages, Genome Evolution, Phylogeny, Genetics, Evolutionary Theory, Multidisciplinary, biology, Genetically Modified Organisms, Microbial Mutation, Temperature, Genomics, Hydrogen-Ion Concentration, Electroporation, Capsid, Medicine, Synthetic Biology, Genetic Engineering, Research Article, Biotechnology, Genetic Markers, Evolutionary Processes, Gene Transfer, Horizontal, Ultraviolet Rays, Science, Genome, Viral, Microbiology, DNA sequencing, Open Reading Frames, Genetic Mutation, Escherichia coli, Biology, Gene, Evolutionary Biology, Models, Genetic, Computational Biology, Sequence Analysis, DNA, biology.organism_classification, Open reading frame, Mutation, Calcium, Adsorption, Genome, Bacterial

Abstract

BackgroundUnprecedented progresses in high-throughput DNA sequencing and de novo gene synthesis technologies have allowed us to create living organisms in the absence of natural template.Methodology/principal findingsThe sequence of wild-type S13 phage genome was downloaded from GenBank. Two synonymous mutations were introduced into wt-S13 genome to generate m1-S13 genome. Another mutant, m2-S13 genome, was obtained by engineering two nonsynonymous mutations in the capsid protein coding region of wt-S13 genome. A chimeric phage genome was designed by replacing the F capsid protein open reading frame (ORF) from phage S13 with the F capsid protein ORF from phage G4. The whole genomes of all four phages were assembled from a series of chemically synthesized short overlapping oligonucleotides. The linear synthesized genomes were circularized and electroporated into E.coli C, the standard laboratory host of S13 phage. All four phages were recovered and plaques were visualized. The results of sequencing showed the accuracy of these synthetic genomes. The synthetic phages were capable of lysing their bacterial host and tolerating general environmental conditions. While no phenotypic differences among the variant strains were observed when grown in LB medium with CaCl(2), the S13/G4 chimera was found to be much more sensitive to the absence of calcium and to have a lower adsorption rate under calcium free condition.Conclusions/significanceThe bacteriophage S13 and its variants can be chemically synthesized. The major capsid gene of phage G4 is functional in the phage S13 life cycle. These results support an evolutional hypothesis which has been proposed that a homologous recombination event involving gene F of quite divergent ancestral lineages should be included in the history of the microvirid family.

Published

2012